Techniques to Overcome Communication Lag Between Terminals Performing Video Mirroring and Annotation Operations

ABSTRACT

Techniques are disclosed for overcoming communication lag between interactive operations among devices in a streaming session. According to the techniques, a first device streaming video content to a second device and an annotation is entered to a first frame being displayed at the second device, which is communicated back to the first device. Responsive to a communication that identifies the annotation, a first device may identify an element of video content from the first frame to which the annotation applies and determine whether the identified element is present in a second frame of video content currently displayed at the first terminal. If so, the first device may display the annotation with the second frame in a location where the identified element is present. If not, the first device may display the annotation via an alternate technique.

BACKGROUND

The present disclosure relates to conferencing applications involvingexchange and annotation of video and, specifically, to techniques formitigating aberrant rendering artifacts induced by communication delayamong conference participants.

Conferencing applications are becoming increasingly popular tools inmodern computing applications. Video conferencing applications, whichonce were cost-prohibitive for all except perhaps the largest ofenterprises, now are widely available to the ordinary consumer. Now,many personal computers, laptop computers, tablet computers and smartphones come equipped with cameras and video conferencing applicationsthat support real time video conferencing over the Internet.

The inventors desire to increase the capability of such conferencingapplications. In particular, the inventors desire to add functionalitythat allows recipients of streamed video to make annotations to thevideo and share them with other conference participants. Suchfunctionality adds complications, however, because, at the time arecipient adds an annotation to a frame being displayed at therecipient's device, that frame no longer is being displayed at thedevice from which it originated. Instead, the frame has been replaced byanother frame at the originating terminal.

Processing delays are induced between terminals by various factors,including video compression, transmission and decompression operations.In the case of video streamed from one device to another, these delayscause a given frame (such as the frame that will be annotated) to bedisplayed then removed from an originating device before it is displayedat a receiving device. Network transmission can be a major contributorto such delays. Processing delays also cause delay in transmission ofannotation data from a receiving device to an originating device. Thus,when an annotation is rendered at an originating device, it may appearto be out of sync with respect to the video it is intended to reference.

Accordingly, the inventors perceive a need in the art for techniquesthat support annotation to video data that is streamed between deviceseven in the presence of communication delays among such devices.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a video conferencing system according to anembodiment of the present disclosure.

FIG. 2 is a functional block diagram of a terminal according to anembodiment of the present disclosure.

FIG. 3 illustrates a method according to an embodiment of the presentdisclosure.

FIG. 4 illustrates exemplary annotations that may be generated accordingto the present disclosure.

FIG. 5 illustrates a method according to another embodiment of thepresent disclosure.

FIG. 6 illustrates a coding timeline that illustrates exemplaryinterplay between terminals operating according to an embodiment of thepresent disclosure.

FIG. 7 illustrates a method according to another embodiment of thepresent disclosure.

FIG. 8 illustrates a method according to a further embodiment of thepresent disclosure.

DETAILED DESCRIPTION

Embodiments of the present invention provide techniques for overcomingcommunication lag between interactive operations among devices in astreaming session. According to the techniques, a first device streamsvideo content to a second device. An annotation is entered to a firstframe being displayed at the second device, which is communicated backto the first device. Responsive to a communication that identifies theannotation, a first device may identify an element of video content fromthe first frame to which the annotation applies and determine whetherthe identified element is present in a second frame of video contentcurrently displayed at the first terminal. If so, the first device maydisplay the annotation with the second frame in a location where theidentified element is present. If not, the first device may display theannotation via an alternate technique.

FIG. 1 illustrates a video conferencing system 100 according to anembodiment of the present disclosure. The system 100 may include a pairof terminals 110, 120 and a communication network 130. The terminals110, 120 may support an interactive communication session between themthat includes exchange of video information, audio information andmetadata information.

The system 100 may establish a communication session 140 that supportsscreen mirroring and annotations between terminals 110, 120, wherescreen content of a first terminal 110 (called a “mirroring terminal”herein) is supplied to a second terminal 120 (a “far-end terminal”) fordisplay and where data representing annotations to the mirroringterminal's content that are entered at the far-end terminal 120 areprovided back to the mirroring terminal 110. The communication session140 may include an exchange of a first stream 142 of data representingscreen content of the mirroring terminal 110 that is provided to thefar-end terminal 120. The communication session 140 may include anexchange of a second stream 144 of metadata representing the annotationmade to the mirroring terminal 110 at the far-end terminal 120.

The screen mirroring and annotation operations 142, 144 may be a part ofa larger communication session 140 between the terminals 110, 120. Thiscommunication session 140 may include exchange of other data stream(s)146, such as bidirectional exchange of audio to carry spoken voice,unidirectional exchange of supplementary video to carry video ofconference participants, and perhaps download of data from externalsources such as media servers (not shown). The present discussion islimited to description of features that relate to the screen mirroringand annotation functions of the present disclosure and, while thesefeatures may work cooperatively with exchange of other data streams 146,terminal operation involving those other data streams 146 is immaterialto the screen mirroring and annotation features unless described herein.

In the example of FIG. 1, the terminals 110, 120 are illustrated astablet computers and notebook computers, respectively, but theprinciples of the present invention are not so limited. Embodiments ofthe present invention find application with personal computers (bothdesktop and laptop computers), smart phones, computer servers, mediaplayers and/or dedicated video conferencing equipment. The network 130represents any number of networks that convey coded video data betweenthe terminals 110, 120, including, for example, wireline and/or wirelesscommunication networks. The communication network 130 may exchange datain circuit-switched and/or packet-switched channels. Representativenetworks include telecommunications networks, local area networks, widearea networks and/or the Internet. For the purposes of the presentdiscussion, the architecture and topology of the network 130 isimmaterial to the operation of the present invention unless explainedhereinbelow.

FIG. 2 is a simplified functional block diagram of a terminal 200according to an embodiment of the present disclosure. The terminal 200may include a video source 210, a display 220, a conference manager 230,a codec 240, and a transceiver 250. The conference manager 230 mayperform operations to support a communication session with anotherterminal (not shown), including exchange of screen content and/orannotations, as desired. The video source 210 may provide video data tothe conference manager 230 that will be mirrored with the other terminalduring a communication session. The display 220 may display video outputof the communication session locally at the terminal 200. The codec 240may perform video compression/decompression operations in support of thecommunication session. The transceiver 250 may perform networktransmission operations in support of the communication session.

As discussed, the video source 210 may supply video to the conferencemanager 230 for exchange with other terminals. A variety of types ofscreen content may be mirrored to another terminal. For example, thevideo source 210 may be a camera that captures video locally at theterminal 200. Alternatively, the video source 210 may be a storagedevice that stores video locally at the terminal 200, which may havebeen captured by a camera at some earlier time. In yet anotherembodiment, the video source 210 may be an application that executeslocally at the terminal 200 and generates video for output to a display.Indeed, the conference manager 230 may be configured to exchange apredetermined portion of a terminal's screen display, without regard tothe number of application(s) that may be active within the area beingexchanged.

The codec 240 may perform compressions and/or decompressions on videoinformation as needed in support of the communication session. Forexample, if screen content is to be mirrored to another terminal (notshown), an encoder 242 may compress a video stream representing themirrored screen content. Compression operations typically exploitspatial and/or temporal redundancies in the video stream to reduce itsbandwidth. Moreover, if screen content is to be mirrored from anotherterminal, for example, transmitted from another terminal for displaylocally at the terminal 200, a decoder 244 may decompress a compressedvideo stream representing the mirror screen content. Decompressionoperations typically invert compression operations that were applied byan encoder of another terminal (not shown) to recover a source videostream. The codec 240 also may perform compression and/or decompressionoperations on other video streams, such as streams 146 (FIG. 1).Compression/decompression operations may be lossy processes, in whichcase, a recovered video stream may exhibit some loss of content withrespect to its source video stream. In an embodiment, the codec 240 mayoperate according to a predetermined coding protocol such as HEVC/H.265,H.264, MPEG-4 and the like.

The transceiver 250 may perform transmission and/or reception operationson data representing the communication session. The transceiver 250 mayinclude a transmitter 252 that may format coded session data intotransmission units for transmission to a network (not shown). Thetransceiver 250 may merge session data from a variety of sources,including coded video data from the encoder 242, coded audio data froman audio codec (not shown), session control information from acontroller (not shown) and other sources of ancillary streams (also notshown). The transceiver 250 may build a unitary transmission stream fromthese sources, format the transmission stream into transmission unitsthat are appropriate for communication via the network, schedule thetransmission units for transmission and ultimately transmit thosetransmission units as scheduled.

The transceiver 250 also may include a receiver 254 for reception ofdata transmitted to the terminal 200 from other sources, includinganother terminal (not shown). The receiver 254 may receive transmissionunits from the network (not shown), buffer them to reconstruct areceived data stream therefrom, parse the received data stream into itsconstituent elements and distribute those elements to appropriateprocessing elements. For example, with respect to coded video datareceived from the other terminal (not shown), the receiver 254 mayprovide the coded video data to a decoder 244 in the codec 240.

The conference manager 230 may perform operations to enable the screenmirroring and/or annotation features as dictated by session controloperations. For example, the conference manager 230 may engage screenmirroring in response to user commands entered at the terminal via aninput device (not shown). If a user command identifies a sub-set ofscreen content to be exchanged, the conference manager 230 may build avideo stream from the identified sub-set and feed it to the codec 240for transmission to the other terminal. Alternatively, if the usercommand does not identify which screen content is to be exchanged, theconference manager 230 may build the video stream from a default set ofcontent, for example, a currently-active window being displayed at theterminal 200 or the entirety of screen information being displayed atthe terminal 200. The conference manager 230 also may respond to usercommand(s) identifying private content and may redact such content fromthe video stream even if it ordinarily would be exchanged according todefault conferencing rules. The conference manager 230 may store all ora portion of the video stream it feeds to the codec 240 in local storage235, called a “conference store” herein.

The conference manager 230 may present annotations on a local display220 when it receives data 144 (FIG. 1) representing such annotationsfrom another terminal. The conference manager 230 may interpretannotation data received from the network and, in certain applicationsof the present disclosure, merge it with video data received either fromthe network or from the conference store 235 before rendering it on thedisplay 220. The embodiments are discussed hereinbelow.

Although the discussion of FIG. 1 makes reference to a mirroringterminal 110 and a far-end terminal 120, these labels are employedmerely to distinguish between terminal roles in a given conference. Inpractice, a single terminal 200 may operate in the role as a mirroringterminal or as a far-end terminal (and, sometimes, as both types ofterminals) as dictated by user control. The conference manager 230,therefore, may include software control to stream video to other deviceswhen the terminal 200 is commanded to operate as a mirroring terminaland also may include software control to add annotations and transmitthem to other devices when the terminal 200 is commanded to operate as afar-end terminal.

FIG. 2, as discussed, is a simplified functional block diagram only. Inpractice, the terminal 200 may include other components (not shown) tosupport other functionality of the communication session, includinginput/output devices and codecs for audio, user interface controls andthe like. Such components are omitted from FIG. 2 merely to simplify thepresent discussion.

FIG. 3 illustrates a method 300 according to an embodiment of thepresent disclosure. According to the method 300, a terminal may bufferall frames that it transmits to a far-end terminal (box 310). When afar-end terminal reports an annotation, the annotation may be identifiedby a frame identifier, an annotation location and data representing theannotation. In response, the method 300 may retrieve the framereferenced by the frame identifier from buffer storage (box 320). Themethod 300 may determine whether a scene change has occurred between theframe referenced by the frame identifier and a current frame beingdisplayed at the terminal (box 330). If no scene change has occurred,the method 300 may attempt to match a location of the annotation in thebuffered frame to a location in the current frame being displayed (box340). If the match is successful (box 350), the method may display theannotation shifted to a location in the current frame that matches theannotation in the buffered frame (box 360). If the match isunsuccessful, then the method 300 may display the buffered frame andannotation in a new window at the terminal (box 370).

In another embodiment, the method 300 may shift display of video at themirroring terminal to center the annotation and its associated contentwithin a display window of the mirroring terminal (box 380).Alternatively, the method 300 may shift display of video at themirroring terminal to keep the annotation and its associated content ata location identified by the report received from the far-end terminal.

FIG. 4 illustrates exemplary annotations that may be generated by themethod of FIG. 3. FIG. 4(a) illustrates a frame that may be displayed ata far-end terminal when an annotation is created. The frame may have anidentifier F1 associated with it. As illustrated, the annotation may bea rectangle drawn over a portion of the mirrored screen content havingits origin at a position X1, Y1 within the area of the displayedcontent. In this example, the far-end terminal may transmit to themirroring terminal annotation information that indicates the annotationwas entered at frame F1, which identifies its location as X1, Y1 andalso identifies information about the annotation itself (e.g., the typeof annotation created, its size and other properties that may be definedby an operator).

FIG. 4(b) illustrates a frame that may be displayed at the mirroringterminal when the annotation information is received from the far-endterminal. The displayed frame will have a likely frame identifier thatis advanced from the frame identifier that represents the frame at whichthe annotation information was entered (e.g., F2>F1). In this example,the mirroring terminal has identified a match between frame content inthe location of frame F1 where the annotation was entered and framecontent in the frame F2 currently being displayed. The mirroringterminal may display a corresponding annotation 420 at a location, shownas X2, Y2, where the matching content appears in frame F2.

FIG. 4(c) illustrates exemplary output of a mirroring terminal in anevent that the method 300 (FIG. 3) could not match the annotation tocontent in frame F2. In this case, the method 300 may open a new window430 and display content of the buffered frame F1 and the annotation 440in a new window 430.

Matching operations may be performed in a variety of ways. Many modernimage processing systems perform motion tracking of image content fromframe to frame, either as part of or preparatory to performing motioncompensated prediction. A conference manager 230 (FIG. 2) may store suchmotion estimates and utilize them to trace an annotation location acrossframes to estimate a location of annotated content in a current frame(e.g., from frame F1 to frame F2 in the example of FIG. 4). Otherprocessing systems employ object recognition, such as face recognition,to recognize objects within frame data. A processing system may performobject recognition on an annotation location within an annotated frameF1, and search for a matching object in the currently-displayed frame F2in an effort to match the annotation to the currently-displayed frame.

In another embodiment, a processing system may augment matchingoperations with audio processing or recognition processes. For example,a terminal may receive audio from a far-end terminal while receiving anannotation. In such an embodiment, the terminal may perform objectrecognition on image data and voice recognition and/or natural langueprocessing algorithms on audio data. If the terminal identifies contentof the audio (for example, the phrase “look at this bird” isrecognized), it may attempt to match audio content with image contentidentified by object recognition. If object recognition detects a birdin the video frame, it may identify an image region that contains thematching object as the region corresponding to the annotation.

FIG. 5 illustrates a method 500 according to another embodiment of thepresent disclosure. According to the method 500, a terminal that mirrorsits screen content to another terminal may buffer only the frames thatfollow scene changes (box 510). When the method 500 receives dataindicating that an annotation has been entered at another terminal, theannotation data may identify the annotated frame by its frame ID. Inresponse, the method 500 may search in the conference store for abuffered frame having a frame ID that precedes the frame ID identifiedin the annotation data (box 520). If a matching frame is identified, themethod 500 may retrieve the buffered frame and display it in a newwindow, along with the annotation (box 530).

Alternatively, when a matching frame is identified, the method 500 maydetermine whether a scene change has occurred between the matching framethat is identified in the conference store and a current frame beingdisplayed (box 540). If a scene change has occurred, then the method 500may advance to box 530 and cause the buffered frame to be displayed in anew window, along with the annotation. If a scene change has notoccurred, however, the method 500 may attempt to match a region in thebuffered frame that is referenced by the annotation to image content inthe current frame being displayed (box 550). If the match is successful(box 560), the method 500 may shift display of the annotation to alocation of the matching region of the current frame (box 570). If not,however, then the method may advance to box 530.

In another embodiment, a far-end terminal may send an annotation alongwith a compressed representation of the annotated video frame that itwas displaying at the time of the annotation. The far-end terminal maycompress the video frame independently of other frames that it transmitsto the near end terminal. Alternatively, it may be compressed using aframe stored by the mirroring terminal as a prediction reference, forbetter compression efficiency. In this latter embodiment, the referenceframe would be a frame initially used by the mirroring terminal to codevideo data sent from the mirroring terminal to the far end terminal;when used for purposes of annotation, the mirroring terminal may re-usethe reference frame as a prediction reference for coding of theannotated frame and transmission back to the mirroring terminal.

FIG. 6 illustrates a coding timeline 600 that illustrates exemplaryinterplay between a mirroring terminal 610 and an annotating terminal620 operating according to the method of FIG. 5. During operation, themirroring terminal 610 may recognize scene changes at frames precedingframes F10 and F1000. The mirroring terminal 610 may store these frameslocally. It may code and transmit to the annotating terminal 620 allframes designated by a user as subject to the mirroring operation. Inthis example, assume that the mirrored video includes frames havingframe IDs F10-F1000.

The annotating terminal 620 may render the mirrored video at some timelater than the rendering times of those frames at the mirroring terminal610. Thus, where FIG. 6 illustrates frame F10 as being rendered by themirroring terminal 610 at time t0, frame F10 may be rendered by theannotating terminal 620 at time t1, owing to delays induced by coding,transmission and decoding. Similarly, FIG. 6 illustrates frame F1000being rendered by the mirroring terminal 610 at time t3 but beingrendered by the annotating terminal 620 at time t4. Although FIG. 6illustrates these delays as being identical for each rendered frame, inpractice, the delays are likely to be variable.

In the example of FIG. 6, a user may begin an annotation at frame F500at time t2. The annotating terminal 620 may transmit data representingthe annotation back to the mirroring terminal, which may not be receivedby the mirroring terminal until sometime after frame F1000 was rendered.The mirroring terminal 610 may identify which of the buffered frames F10and F1000 have a frame ID that precedes frame ID F500 (in this case,frame F10). The mirroring terminal 610 also may determine that a scenechange has occurred between frame F10 and the frame currently beingdisplayed. Accordingly, the mirroring terminal 610 may cause thebuffered frame F10 to be displayed with the annotation entered at frameF500.

The method of FIG. 5 may conserve resources in a way that othermirroring systems may not. As compared to the embodiment of FIG. 3, forexample, the method 500 of FIG. 5 may require only frames that follow ascene change to be stored by a terminal. The embodiment of FIG. 3,however, causes all mirrored frames to be buffered for a correspondingtime. Accordingly, storage resources required to implement the method ofFIG. 5 likely will be reduced as compared to other embodiments.

A variety of scene change detection techniques may be used. For example,discontinuous operation of a camera or switches among cameras in amulti-camera system (e.g., front camera to back camera or vice versa)may cause corresponding discontinuities in video supplied by the camera.For video streams generated by applications or video production systems,scene changes may be detected by frame-by-frame comparisons that detectloss of correlation between frames. Similarly, losses of correlationsmay be induced by rapid movement of a continuously-operating camera,which causes the camera to capture information from a first angularposition, then from a second angular position that replaces imageinformation in the camera's field of view; such position changes may bedetected by a motion sensor such as a gyroscope or accelerometer. Theprinciples of the present disclosure may work cooperatively with any ofthese scene change detection techniques.

FIG. 7 illustrates a method 700 according to another embodiment of thepresent disclosure. According to the method 700, a conference managerhas access to processes resident at a terminal (such as an operatingsystem or applications) that build screen content from various videosources. The method 700, therefore, may identify screen objects thatcorrespond to different locations of mirrored screen content. As theconference manager streams mirrored video to another terminal, themethod 700 may store information identifying, for each mirrored frame,the object(s) in the mirrored content and their correspondinglocation(s) (box 710).

When the method 700 receives data identifying an annotation, theannotation may be identified by frame ID, the annotation's location anddata defining how the annotation is to be rendered. In response to theannotation data, the method 700 may identify and retrieve a bufferedframe that corresponds to the annotation location (box 720). It mayattempt to identify an object that is subject to the annotation (box730). If the method 700 recognizes the object that is subject to theannotation, the method 700 may determine whether that object is presentin the currently displayed frame (box 740). If so, the method 700 mayshift the location of the annotation to the location of the object incurrent frame and display the annotation (box 750).

If the annotation could not be matched to a content object (box 730) orthe content object no longer appears in the current frame (box 740), themethod 700 may enter an error condition (box 760). The method 700 mayrespond to an error condition in a variety ways. First, the method 700simply may display the annotation at its identified locationnotwithstanding the fact that its associated content object has not beenlocated. This response may be appropriate in implementations where someportions of screen content may not map to identified objects (forexample, background elements). It also may be appropriate inobject-based implementations where the annotated content object has beenremoved from view. The loss of the annotated content object will becomeapparent at the annotating terminal once it is rendered and an operatorlikely will remove the annotation on his/her own volition.

Alternatively, when an annotated content object is no longer in screencontent, the method 700 may display an error indication at theannotating terminal (not shown). The notification may indicate thatannotation data was received but cannot be rendered.

Further, when an annotated content object is no longer in screencontent, the method 700 may cause an error notification to betransmitted from the mirroring terminal to an annotating terminal thatoriginated the annotation. In response, the annotating terminal mayremove the annotation (not shown) or prompt the operator to relocate theannotation so it better matches to content objects displayed at theannotating terminal.

FIG. 8 illustrates a method 800 according to another embodiment of thepresent disclosure. In this embodiment, the method 800 may have accessto applications and/or operating system elements that generate videocontent to be mirrored to a far-end device. As the conference managerstreams mirrored video to another terminal, the method 800 may transmita metadata map that contains identifiers of content objects in themirrored video, which may be supplied by these applications and/oroperating system elements, and locations within the frames that theobjects occupy (box 810).

When a user at a far-end terminal adds an annotation to the mirroredvideo, a far-end terminal may report the annotation by identifying anobject identifier that is associated with the annotation's location anddata representing the annotation. The method 800 may determine whetherthe content object is present in a current frame being displayed at themirroring terminal (box 820). If the content object is present in thecurrent frame, then the method may shift the annotation to a locationwhere the content object is located in the current frame (box 830),which depending on object movement may or may not be in the samelocation as in the annotated frame. If the content object is not presentin the current frame, then the method 800 may respond to an errorcondition (box 840) as discussed in any of the foregoing embodiments.

In another embodiment, video mirroring may be performed for videocontent that is generated by an application that is executingconcurrently on both the near end terminal and the far-end terminal. Insuch an embodiment, the far-end terminal may identify an annotation byidentifying an application object to which the annotation refers. Then,the method may operate in a manner that is analogous to box 830 bydetermining whether the application object is currently displayed by thenear end terminal. If so, the method may display the annotation over theapplication object. If not, the method may respond to an error conditionas discussed hereinabove.

The foregoing discussion has described operation of the embodiments ofthe present disclosure in the context of terminals that embody encodersand/or decoders. Commonly, these components are provided as electronicdevices. They can be embodied in integrated circuits, such asapplication specific integrated circuits, field programmable gate arraysand/or digital signal processors. Alternatively, they can be embodied incomputer programs that execute on personal computers, notebookcomputers, tablet computers, smartphones or computer servers. Suchcomputer programs typically are stored in physical storage media such aselectronic-, magnetic- and/or optically-based storage devices, wherethey are read to a processor under control of an operating system andexecuted. Similarly, decoders can be embodied in integrated circuits,such as application specific integrated circuits, field-programmablegate arrays and/or digital signal processors, or they can be embodied incomputer programs that are stored by and executed on personal computers,notebook computers, tablet computers, smartphones or computer servers.Decoders commonly are packaged in consumer electronics devices, such asgaming systems, DVD players, portable media players and the like; andthey also can be packaged in consumer software applications such asvideo games, browser-based media players and the like. And, of course,these components may be provided as hybrid systems that distributefunctionality across dedicated hardware components and programmedgeneral-purpose processors, as desired.

Several embodiments of the disclosure are specifically illustratedand/or described herein. However, it will be appreciated thatmodifications and variations of the disclosure are covered by the aboveteachings and within the purview of the appended claims withoutdeparting from the spirit and intended scope of the disclosure.

1-26. (canceled)
 27. A method, comprising: displaying video streamedfrom a distant device, responsive to operator control, annotating thestreamed video at a local device, transmitting to the distant device acommunication identifying the annotation and an identifier of theannotation's location in a currently-displayed frame at the distantdevice.
 28. The method of claim 27, wherein the communication includes aframe identifier (ID) of a first frame buffered at the distant deviceand a location of the annotation in the first frame.
 29. The method ofclaim 27, wherein the communication includes an object identifierrepresenting an object in a first frame at the distant devicecorresponding to a currently-displayed frame at the local device. 30.The method of claim 27, wherein the communication identifies an objectin the streamed video generated by an application executing in common onthe local device and the distant device.
 31. The method of claim 27,wherein the communication includes audio content identifying an objectin the annotated streamed video.
 32. The method of claim 27, wherein thecommunication identifying the annotation includes a type of theannotation, a size of the annotation, and at least one additionalproperty of the annotation as defined by the operator of the localdevice.
 33. The method of claim 27, further comprising: coding theannotated streamed video at the local device using a reference framereceived with the streamed video prior to the transmitting.
 34. Themethod of claim 27, further comprising: coding an annotated video framein the received streamed video independently of other frames transmittedto the distant device.
 35. An annotating device, comprising: aconference manager to process streamed video received from an otherdevice at the annotating device, a codec, having an input for thestreamed video and an output for coded annotated video data, a displayto display streamed video received at the annotating device, and atransceiver, having a transmitter for the coded annotated video data anda receiver for receiving communications from the other device, wherein,responsive to operator control identifying an annotation entered at theannotating device to a first frame in the streamed video, the conferencemanager transmits, from the transmitter, the annotated streamed videoincluding communication identifying the annotation and an identifier ofthe annotation's location in a currently-displayed frame at the otherdevice.
 36. The annotating device of claim 35, wherein the communicationincludes a frame identifier (ID) of a first frame buffered at the otherdevice and a location of the annotation in the first frame.
 37. Theannotating device of claim 35, wherein the communication includes anobject identifier representing an object in a first frame at the otherdevice corresponding to a currently-displayed frame at the annotatingdevice.
 38. The annotating device of claim 35, wherein the communicationidentifies an object in the streamed video generated by an applicationexecuting in common on the annotating device and the other device. 39.The annotating device of claim 35, wherein the communication includesaudio content identifying an object in the annotated streamed video. 40.The annotating device of claim 35, wherein the communication identifyingthe annotation includes a type of the annotation, a size of theannotation, and at least one additional property of the annotation asdefined by the operator of the annotating device.
 41. The annotatingdevice of claim 35, wherein the codec is configured to: code theannotated streamed video at the annotating device using a referenceframe received with the streamed video prior to the transmitting. 42.The annotating device of claim 35, wherein the codec is configured to:code an annotated video frame in the received streamed videoindependently of other frames transmitted to the other device.
 43. Anon-transitory computer readable medium having stored thereon programinstructions that, when executed by a processing device, cause thedevice to perform a method, comprising: receiving streaming videocontent from a first terminal at a second terminal; and responsive to acommunication identifying an annotation entered at the second terminalto a first frame of video content, transmitting to the first device acommunication identifying the annotation and an identifier of theannotation' s location in a currently-displayed frame at the distantdevice.
 44. The medium of claim 43, wherein the communication includes aframe identifier (ID) of a first frame buffered at the distant deviceand a location of the annotation in the first frame.
 45. The medium ofclaim 43, wherein the communication includes an object identifierrepresenting an object in a first frame at the first terminalcorresponding to a currently-displayed frame at the second terminal. 46.The medium of claim 43, wherein the communication identifies an objectin the streamed video generated by an application executing in common onthe first terminal and the second terminal.
 47. The medium of claim 43,wherein the communication includes audio content identifying an objectin the annotated streamed video.
 48. The medium of claim 43, wherein thecommunication identifying the annotation includes a type of theannotation, a size of the annotation, and at least one additionalproperty of the annotation as defined by the operator of the secondterminal.
 49. The medium of claim 43, wherein the program instructionsthat, when executed by a processing device, further cause the device toperform: coding of the annotated streamed video at the second terminalusing a reference frame received with the streamed video prior to thetransmitting.
 50. The medium of claim 43, wherein the programinstructions that, when executed by a processing device, further causethe device to perform: coding of an annotated video frame in thereceived streamed video independently of other frames transmitted to thefirst terminal.
 51. A method of annotating data between terminals,comprising: decoding and displaying coded video received from a distantterminal, responsive to an annotation entered by a user, codingaccording to predictive coding techniques a displayed frame beingannotated, the coding using a prediction reference stored by the distantterminal, and transmitting the coded frame and data representing theannotation to the distant terminal.
 52. The method of claim 51, whereinthe transmitting includes transmitting a frame identifier (ID) of afirst frame buffered at the distant terminal and a location of theannotation in the first frame.
 53. The method of claim 51, wherein thetransmitting includes transmitting an object identifier representing anobject in a first frame at the distant terminal corresponding to thedisplayed frame.
 54. The method of claim 51, wherein the transmittingincludes identifying an object in the coded video generated by anapplication executing in common on a local device and the distantterminal.
 55. The method of claim 52, wherein the transmitting includestransmitting includes audio content identifying an object in theannotated coded video.
 56. The method of claim 52, wherein thetransmitting includes identifying the annotation including a type of theannotation, a size of the annotation, and at least one additionalproperty of the annotation as defined by the operator of a local device.